The Association of Science Technology Centers (ASTC) will plan a multi-year initiative to build the capacity of science to facilitate the implementation of school/science center partnerships. ASTC'S intention is to organize a network a 'learning communities' in five prominent interest areas, identified by the field, to help science museums focus more effectively on school science education, and develop close collaboration with schools to influence systemic change. During the planning phase, ASTC will: Organize and convene a national advisory committee Develop a position paper to inform and engage the field for school/science center collaboration. Identify leadership institutions and their partners among school systems, and form a core group of facilities and personnel for the leaning communities. Investigate needs in existing practices and develop an appropriate range of resources, services, and activities. Determine priorities for phased implementation of learning communities and related program activities. Conduct research to identify useful techniques and approaches for program documentation, research, and evaluation.
Chemistry in the Community (ChemCom) was designed to provide an attractive, open access route for all high school students to the realm of relevant and useful chemical phenomena. What began as a dream a few years ago is now a well-developed high school program brought about by the concerted efforts of high school teachers, college and university professors, and industrial chemists and financed by the National Science Foundation and the American Chemical Society. This three-year project is designed as a partnership to support the dissemination of the Chemcom curriculum. Specially selected teachers will be educated so that they can become resource teachers who will conduct ChemCom inservice workshops throughout the country. These resource teachers are expected to represent as many as 150 school systems and will reach as many as 2,000 teachers with their inservice programs. The project also includes a series of networking activities entitled "An Evening with ChemCom, the establishment of a computer network, and the production of a newsletter. The evaluation will focus on the effectiveness of this particular model for implementing curriculum change. The total cost sharing (ACS, Publisher, School Systems) is expected to be almost five times the NSF request.
Through a collaboration of the DuPage Children's Museum, Argonne National Laboratory, and National-Louis University, a three-element project is being conducted focusing on the following: 1) a research component that studies children's naive perceptions of the phenomena of air and wind energy, 2) an exhibition component that uses the project research to design, develop, and construct a 3- 4,000 square foot "process" oriented exhibition with a 2-story exhibit tower and 12-15 replicable exploratory workstations, 3) a program component that offers explorations for children adapted for museums, preschools and elementary school classrooms. Target audiences include young children and their parents, pre- and in- service early childhood teachers, and museum professionals interested in reaching very young children.
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TEAM MEMBERS:
Rebecca Lindsay
resourceprojectProfessional Development, Conferences, and Networks
This project is aimed at perfecting and testing a new instructional method to improve the effectiveness of introductory physics teaching. the methods has two chief characteristics: 1) a systematic challenge to common sense misconceptions about the physical world, and 2) an emphasis on models and modeling as basic to physical understanding. Two versions of the method will be tested. The first version is designed especially for high school physics. It emphasizes student development of explicit models to interpret laboratory activities. After an initial test, this version will be taught to high school physics teachers in a summer Teacher Enhancement Workshop, and its effect on their subsequent teaching will be evaluated. Teachers with weak as well as strong backgrounds will be included. A special effort will be made to include females and minorities. The second version will be tested in a special college physics course designed to prepare students with weak backgrounds for a standard calculus based physics course. It emphasizes modeling techniques in problem solving. This project is jointly supported by the Division of Materials development, Research and Informal Science Education and the Division of Teacher Preparation and Enhancement.
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TEAM MEMBERS:
David HestenesMalcolm Wells
resourceprojectProfessional Development, Conferences, and Networks
Scientists and engineers are an underutilized resource in motivating students and assisting classroom teachers in teaching science. Pilot programs have demonstrated the value of preparing scientists for what to expect when they enter the classroom, how to incorporate the school curriculum into their program, and how best to reach the goal of making their visits a "never to be forgotten" life changing experience for students. The concept of a Survival Kit is an outgrowth of a Scientist-in-Residence program at the North Carolina Museum of Life and Science which has successfully matched scientists and public school classrooms locally since 1982. The North Carolina Museum of Life and Science proposes to conduct meetings for staff and outside educational specialists to identify the materials and strategies needed to prepare scientists to enter school classrooms. The final report of these meetings will include mechanicals of a Scientist Survival Kit, which can be disseminated across the country, and an evaluation report of how the kits can be and are used. Dr. Mark St. John, Inverness Associates, a professional evaluator noted for his work with nationally significant science education projects, will provide local and national evaluation through surveys and meetings to give a picture of the issues involved in establishing and maintaining programs of scientists in the schools and the role played by the Scientist's Survival Kit in furthering this aim.
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TEAM MEMBERS:
Thomas KrakauerGeorgiana Searles
resourceprojectProfessional Development, Conferences, and Networks
This project will test an instructional strategy designed to increase the pool of minority students who are successful in their study of algebra and higher mathematics courses. Since 1979, the Comprehensive Math and Science Program at Columbia University has been developing an instructional model designed to give all entering ninth grade students the opportunity to work to their highest level of capacity in mathematics. Key features of the model are a zero-based start, which makes no assumptions on students' prior mathematics background, and a complementary curriculum, which provides a set of parallel, interlocking mathematics courses that substantially increases the rate of mathematics instruction over a four semester period. Preliminary tests of the model in New York City schools have yielded encouraging results. In the current project, the instructional materials will be completed and the model will be extensively tested in New York City and in Fulton County, Georgia. The testing will be accompanied by the development of an apprenticeship model for teacher training, which will pair new teachers with experienced teachers in the interlocking courses of the program.
Cognitive research indicates that science experts commonly use diagrams as mediational tools for reasoning visually. But in science education materials and practices, visuals are typically "aids" rather than fundamental representations. This research will examine how students learn to comprehend, use, and construct diagrams as thinking tools. It will focus on the diagram-dense field of beginning optics. The project has two interacting phases: research on how students understand static optics diagrams, and development and refinement of prototype computer- based dynamic diagrams and diagramming tools. Specific tasks are: (1) Pilot research, and analysis of diagrams in optics texts, (2) research on instructional practices with these diagrams, (3) research on student understanding and use of diagrams, (4) design and develop interactive diagrams and a dynamic diagram-construction kit, (5) carry out research with prototypes, and (6) formulate and disseminate implications for creation and use of interactive diagrams in science education. Such research on visual education in science will help guide development of new curricula and software for science education. The project team of cognitive scientists, science educators, graphics specialists, and systems developers is devoted to promoting learning and reasoning in science with new data, theory, and innovative prototypes of dynamic diagrams. These interdisciplinary activities more directly link science education research, materials development, and classroom activities. Cost sharing is provided by the Institute for Research on Learning which is contributing indirect costs and APPEL which is contributing four MacIntosh II systems.
Parent Partners in School Science (PPSS) is a partnership project between The Franklin Institute and the Philadelphia School District. This is a three and one-half year program which will provide a pivotal role for the informal science learning center to be a facilitator in parental support of K-4 school instruction in science. The PPSS program will involve teachers, families and children in grades K-2 the first year, grades 1-3 the next, and finally grades 2-4 in the third year. The incorporation of the national science standards and working with Home and School Associations (HSA) in the area schools, the program will impact over 3600 children, 5400 parents and 45 educators participating over the life of the project. There are several goals and elements in the program. This will certainly demonstrate how an informal science center supports learning and it is also hoped to become a model for effective parent-teacher and parent-child collaboration to support learning. There will be Exploration Cards developed, which are at-home schince challenges for families, Discovery Days that are museum-based days of science inquiry using the yearly theme, Parent/Teacher Workshops at the museum, and finally a Science Celebration which is a showcase of participants' year-long achievements via an exhibit to be displayed at The Franklin Institute for a month, then traveling the exhibit to participating schools. The project's structure, disseminination acitivites and products are designed for national application and as a model for use in both formal and informal education communities. It is hoped the program will offer new opportunities for science center methology and pratice to provide direct support for the school agenda in science.
The purpose of this project is to enhance African American parental involvement with high school student children by developing skills and strategies for effectively managing the educational careers of their children. It would create a capacity for collaborations with the schools that service African American children by developing the social and organizational infrastructure for continued parental involvement in educational careers. It seeks to increase enrollment and success of Black students in higher-level mathematics and science courses to diminish the race gap in math and science track placements. It uses a quasi-experimental design to implement a series of community workshops designed to enhance knowledge, skills, and strategies for managing placements of children in science and math tracks. The research would create an intervention designed to change the outcome of students. It would conduct ethnographic work to map successful pathways to enrollment in higher-level math courses. It would use findings from these studies to implement workships within the Black communities, and conduct statistical analysis of the growth in achievement as a result of the reduction in course taking.
Project Enhanced Science Learning (PESL) offers learning partners opportunities to engage in authentic scientific inquiry through apprenticeship. Such inquiry is often enabled by dynamic interactions among learning partners in physical proximity. Yet scientific and business practice using Internet and broadband services recognizes that not all partners necessary to an interaction can be co-located. Our vision uses new technologies to extend the collaborative "reach" of PESL to include diverse expertise among remote learners, teachers, and scientists. This work, in atmospheric sciences, extends collaborative media beyond asynchronous text-only email to shared workspaces and two-way audio/video connections that allow for collaborative visualization of science phenomena, data, models - What You See Is What I See (WYSIWIS). Tools for local- and wide-area networked learning environments will enable highly interactive, media-rich communications among learning partners. Research on these learning architectures will provide pedagogy and social protocols for authenticating the science learning experience in classrooms and other spaces. Greater motivation to learn and enhanced science learning in terms of more valid, performance assessments should result from students' participations. The next decade brings widespread, networked multi-media interpersonal computing. This project will provide a blueprint to inform the effective use of interpersonal collaborative media for science education.
Digital image processing offers several possible new approaches to the teaching of a variety of mathematical concepts at the middle-school and high-school levels. There is reason to believe that this approach will be successful in reaching some "at-risk" students that other approaches miss. Since digital images can be made to reflect almost any aspect of the real world, some students may have an easier time taking an interest in them than they might with artificial figures or images resulting from other graphics- oriented approaches. Using computer-based tools such as image processing operators, curve-fitting operators, shape analysis operators, and graphical synthesis, students may explore a world of mathematical concepts starting from the psychologically "safe" territory of their own physical and cultural environments. There is reason to hope that this approach will be particularly successful with students from diverse backgrounds, girls and members of minority groups, because the imagery used in experiments can easily be tailored to individual tastes. The work of the project consists of creating detailed designs of the learning modules, implementing them on microcomputers, and evaluating their effectiveness in a variety of ways, using trials with students at Rainier Beach High School, which is an urban public high school having an ethnically diverse student body and a Macintosh computer laboratory.
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TEAM MEMBERS:
Steven TanimotoMichele LeBrasseurJames King
Led by Washington University, Making Natural Connections: An Authentic Field Research Collaboration (DRL-0739874), is a series of two field-based informal science education programs in environmental biology targeting St. Louis area teenagers. The project aims for engagement of science research institutions and career scientists in the execution of informal science education programming, bringing real and dynamic context to the science content and allowing for deep and transparent career exploration by teenage participants. Project goals include (1) providing a model for integration of informal science education into the research and restoration projects at biological field stations and nature reserves, (2) communicating current environmental biology research to audiences outside the research community, and (3) influencing the entry of pre-college students into the science career pipeline. The project is a collaborative partnership between Washington University’s Tyson Research Center and the Missouri Botanical Garden’s Shaw Nature Reserve. The Shaw Institute for Field Training (SIFT) program trains St. Louis area high school students in scientific exploration of the natural world at Shaw Nature Reserve. During a one-week training session in June, teens are introduced to a variety of Missouri ecosystems and gain skills necessary to conduct field research, including plant and animal identifications, biotic sampling and census techniques, testing of abiotic factors, and training in the use of maps, compass and GPS. During the rest of the summer and school year, teens are involved in important research and restoration activities at Shaw, Tyson Research Center and other field research sites in the St. Louis area. Fieldwork opportunities may include invasive species management, prairie reconstruction, plant and animal inventories, and prescribed burns. The Tyson Environmental Research Fellowships (TERF) program places high school students as summer interns on ecology and environmental biology research teams at Tyson Research Center. Selected teen participants have successfully completed the SIFT program and apply their field skills to ongoing research projects at Tyson and other partnering research sites. During the summer, the four-week program provides teens with exposure to a variety of field science experiences and skills. TERF teens work alongside university scientists, post-doctoral researchers, graduate students and undergraduate students. The TERF program provides a cultural apprenticeship in university-based environmental biology research and training in scientific communication. It is an advanced summer experience modeled on the undergraduate research internships offered at Tyson. During the following school year, participants work on posters and presentations for symposia at Washington University and Tyson and at community fairs, and their posters are displayed at Shaw Nature Reserve. A national dissemination workshop for informal science educators, high school biology teachers, and research scientists provides the necessary materials and background to replicate the project design in other locales. The summative evaluation will address impacts on teenage participants (engagement, cognitive and emotional support, competence, career viability, experiential learning) and professional audiences (implementation of teen program, program components, impacts on mentoring scientists). The strategic impact of this project results from the integration of teenage immersion experiences into research activities at a university-based facility. This model of informal science training activities leading into participation in authentic research may be transferable to other STEM disciplines.
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TEAM MEMBERS:
Phyllis BalcerzakPeter RavenSusan FlowersKim Medley